RU2000130055A - HIERARCHIC COMMUNICATION NETWORK FOR TRANSMISSION OF MESSAGES WITH COMPLETED INFORMATION - Google Patents

Claims (16)

1. A hierarchical communication network for transmitting messages with compressed information, which is composed of local networks of various levels, which are connected by multi-port to the internal bus transition nodes interconnected, characterized in that each subscriber connected to a local network is equipped with multi-level coding programs the message to be transmitted, by programs of multilevel decoding of a message received over the network, as well as by programs of replenishment of the hierarchy arising from this at the subscriber eskoy database; at the same time, the sender's subscriber address is included in the information part of the encoded message transmitted over the network.  2. The network according to claim 1, characterized in that the information part of the message further includes an index (number) of the sender encoding-decoding program.  3. The network according to claim 1, characterized in that the sender information encoding and decoding program parameters are additionally included in the information part of the message.  4. The network according to claim 1, characterized in that the sender encoding and decoding program is additionally included in the information part of the message.  5. The network according to claim 1, characterized in that the information part of the message additionally includes a code that is not ready to receive the message.  6. The network according to claim 1, characterized in that the readiness to receive the message is additionally included in the information part of the message.  7. The network according to claim 6, characterized in that it maintains the identity of the databases in an interconnected pair of databases, for which, when replenishing only one database from an interconnected pair of bases, each element that replenishes any level of this database at any address, send to the same address to the same level as another base of this pair.  8. The network according to claim 7, characterized in that when replenishing only one base from an interconnected pair of bases, each element replenishing at any address a level of this base is fixed in a predetermined buffer of this base, and at the end of the replenishment process bases, all elements fixed in the buffer during this replenishment process are sent to another base of this pair at the same levels and to the same addresses that they have in the first base of this pair.  9. The network according to claim 7, characterized in that when replenishing each base from an interconnected pair of bases at non-intersecting time intervals, each element replenishing any level at any address in the same base is forwarded to the same address at the same level another base from this pair.  10. The network according to claim 9, characterized in that when replenishing each base from an interconnected pair of bases at non-intersecting time intervals at the beginning of the process of replenishing any base from this pair, a buffer is allocated from this pair in this database and each element replenishing a level by any address of this base is fixed in this buffer, and at the end of the next process of replenishing this database and before the start of the period of time allotted for replenishing another database of this pair, all elements fixed in the buffer during this next process of replenishing send to another base of this pair to the same levels and to the same addresses that they have in the first base of this pair.  11. The network according to claim 10, characterized in that the replenishment of each base from an interconnected pair of bases at non-intersecting time intervals, each element that replenishes a level at any address of any base from this pair of bases is fixed in a predetermined buffer of this base, and at the end of the next process of replenishing this base and before the start of the period of time allotted for replenishing another database of this pair, all the elements fixed in the buffer during this next process of replenishing are sent to another database of this pair the same levels and under the same address, they are at first base this pair.  12. The network according to claim 10, characterized in that when replenishing each base from an interconnected pair of bases at overlapping time intervals at the beginning of the next process of replenishing any base from this pair, a buffer is allocated from this pair in this database and each element designed to replenish this base are fixed in the buffer, and the transfer of the elements fixed on each buffer in this pair of bases to both their own and to the other bases of this pair is carried out according to the exchange protocol established for this pair of bases in such a way that identical elements replenishing the basics of this pair on each the same level in both databases are on the same addresses without forwarding already existing at that level elements.  13. The network according to p. 12, characterized in that the fixation of the elements intended to replenish the bases of the pair is made in the buffer provided for each base of this pair in advance.  14. The network according to p. 7 or p. 8, or p. 9, or p. 10, or p. 11, or p. 12, or p. 13, characterized in that several databases for one of each interconnected pair databases are combined under one address at a subscriber point.  15. The network under item 7 or item 8, or item 9, or item 10, or item 11, or item 12, or item 13, or item 14, characterized in that in each database , which is not included in any subscriber station, as well as in each set of databases of each subscriber station, replenished according to the same program, include the same non-replenished hierarchical database, arranging everywhere its elements at each level for the same addresses.  16. The network according to claim 1, characterized in that the information part of the message further includes a code to refuse to receive messages.